RNAseq Analysis of the Response of Arabidopsis thaliana to Fractional Gravity Under Blue-Light Stimulation During Spaceflight

Introduction: Traveling to nearby extraterrestrial objects having a reduced gravity level (partial gravity) compared to Earth’s gravity is becoming a realistic objective for space agencies. The use of plants as part of life support systems will require a better understanding of the interactions among plant growth responses including tropisms, under partial gravity conditions. Materials and Methods: Here, we present results from our latest space experiments on the ISS, in which seeds of Arabidopsis thaliana were germinated, and seedlings grew for six days under different gravity levels, namely micro-g, several intermediate partial-g levels, and 1g, and were subjected to irradiation with blue light for the last 48 h. RNA was extracted from 20 samples for subsequent RNAseq analysis. Transcriptomic analysis was performed using the HISAT2-Stringtie-DESeq pipeline. Differentially expressed genes were further characterized for global responses using the GEDI tool, gene networks and for Gene Ontology (GO) enrichment. Results: Differential gene expression analysis revealed only one differentially expressed gene (AT4G21560, VPS28-1 a vacuolar protein) across all gravity conditions using FDR correction (q < 0.05). However, the same 14 genes appeared differentially expressed when comparing either micro-g, low-g level (< 0.1g) or the Moon g-level with 1g control conditions. Apart from these 14-shared genes, the number of differentially expressed genes was similar in microgravity and the Moon g-level and increased in the intermediate g-level (< 0.1g), but it was then progressively reduced as the difference with the Earth gravity became smaller. The GO groups were differentially affected at each g-level: light and photosynthesis GO under microgravity, genes belonged to general stress, chemical and hormone responses under low-g, and a response related to cell wall and membrane structure and function under the Moon g-level. Discussion: Transcriptional analyses of plants under blue light stimulation suggests that root blue-light phototropism may be enough to reduce the gravitational stress response caused by the lack of gravitropism in microgravity. Competition among tropisms induces an intense perturbation at the micro-g level, which shows an extensive stress response that is progressively attenuated. Our results show a major effect on cell wall/membrane remodeling (detected at the interval from the Moon to Mars gravity), which can be potentially related to graviresistance mechanisms.

[1]  Huijun Guo,et al.  Transcriptome and proteomic analyses reveal multiple differences associated with chloroplast development in the spaceflight-induced wheat albino mutant mta , 2017, PloS one.

[2]  R. Herranz,et al.  Novel, Moon and Mars, partial gravity simulation paradigms and their effects on the balance between cell growth and cell proliferation during early plant development , 2018, npj Microgravity.

[3]  William L. Poehlman,et al.  RNA-seq analyses of Arabidopsis thaliana seedlings after exposure to blue-light phototropic stimuli in microgravity. , 2019, American journal of botany.

[4]  Ian R. Castleden,et al.  SUBA4: the interactive data analysis centre for Arabidopsis subcellular protein locations , 2016, Nucleic Acids Res..

[5]  Robert J Ferl,et al.  Genetic dissection of the Arabidopsis spaceflight transcriptome: Are some responses dispensable for the physiological adaptation of plants to spaceflight? , 2017, PloS one.

[6]  Richard E. Edelmann,et al.  Changes in operational procedures to improve spaceflight experiments in plant biology in the European Modular Cultivation System , 2014 .

[7]  Y. Benjamini,et al.  Controlling the false discovery rate: a practical and powerful approach to multiple testing , 1995 .

[8]  Joshua P Vandenbrink,et al.  Space, the final frontier: A critical review of recent experiments performed in microgravity. , 2016, Plant science : an international journal of experimental plant biology.

[9]  Steven L Salzberg,et al.  HISAT: a fast spliced aligner with low memory requirements , 2015, Nature Methods.

[10]  Mary Hummerick,et al.  Genome-wide expression analysis of reactive oxygen species gene network in Mizuna plants grown in long-term spaceflight , 2014, BMC Plant Biology.

[11]  Francisco Javier Medina,et al.  Microgravity Induces Changes in Microsome-Associated Proteins of Arabidopsis Seedlings Grown on Board the International Space Station , 2014, PloS one.

[12]  F Gòdia,et al.  The MELISSA pilot plant facility as as integration test-bed for advanced life support systems. , 2004, Advances in space research : the official journal of the Committee on Space Research.

[13]  Richard E. Edelmann,et al.  Transcriptome analyses of Arabidopsis thaliana seedlings grown in space: implications for gravity-responsive genes , 2013, Planta.

[14]  Joshua P Vandenbrink,et al.  Preparation of a Spaceflight Experiment to Study Tropisms in Arabidopsis Seedlings on the International Space Station. , 2019, Methods in molecular biology.

[15]  F. Baluška,et al.  Gravity: one of the driving forces for evolution , 2006, Protoplasma.

[16]  Johannes Madlung,et al.  Time-course of changes in amounts of specific proteins upon exposure to hyper-g, 2-D clinorotation, and 3-D random positioning of Arabidopsis cell cultures. , 2007, Journal of experimental botany.

[17]  Robert J Ferl,et al.  Spaceflight transcriptomes: unique responses to a novel environment. , 2012, Astrobiology.

[18]  P. Masson,et al.  Gravitropism in higher plants. , 1999, Plant physiology.

[19]  Gilbert Gasset,et al.  Plant cell proliferation and growth are altered by microgravity conditions in spaceflight. , 2010, Journal of plant physiology.

[20]  Eugénie Carnero-Diaz,et al.  Gravisensitivity and automorphogenesis of lentil seedling roots grown on board the International Space Station. , 2008, Physiologia plantarum.

[21]  Fiona C. Denison,et al.  Spaceflight induces specific alterations in the proteomes of Arabidopsis. , 2015, Astrobiology.

[22]  Joshua P Vandenbrink,et al.  The combined effects of real or simulated microgravity and red-light photoactivation on plant root meristematic cells , 2018, Planta.

[23]  W. Briggs,et al.  Phototropism: Some History, Some Puzzles, and a Look Ahead1 , 2014, Plant Physiology.

[24]  Joshua P Vandenbrink,et al.  A novel blue-light phototropic response is revealed in roots of Arabidopsis thaliana in microgravity , 2016, Planta.

[25]  T. Hoson,et al.  Role of the plant cell wall in gravity resistance. , 2015, Phytochemistry.

[26]  Jens Hauslage,et al.  Ground-based facilities for simulation of microgravity: organism-specific recommendations for their use, and recommended terminology. , 2013, Astrobiology.

[27]  Melanie J Correll,et al.  Comparative transcriptomics indicate changes in cell wall organization and stress response in seedlings during spaceflight. , 2017, American journal of botany.

[28]  Benjamin K Blackman,et al.  Turning heads: the biology of solar tracking in sunflower. , 2014, Plant science : an international journal of experimental plant biology.

[29]  E Brinckmann,et al.  Experiments with small animals in BIOLAB and EMCS on the International Space Station. , 2002, Advances in space research : the official journal of the Committee on Space Research.

[30]  Paul Anthony,et al.  Expression of transcription factors after short-term exposure of Arabidopsis thaliana cell cultures to hypergravity and simulated microgravity (2-D/3-D clinorotation, magnetic levitation) , 2007 .

[31]  Martin Kuiper,et al.  BiNGO: a Cytoscape plugin to assess overrepresentation of Gene Ontology categories in Biological Networks , 2005, Bioinform..

[32]  Sui Huang,et al.  Gene Expression Dynamics Inspector (GEDI): for integrative analysis of expression profiles , 2003, Bioinform..

[33]  J. Kiss Conducting plant experiments in space. , 2015, Methods in molecular biology.

[34]  P. Shannon,et al.  Cytoscape: a software environment for integrated models of biomolecular interaction networks. , 2003, Genome research.

[35]  J. Kiss,et al.  Phototropism and gravitropism in transgenic lines of Arabidopsis altered in the phytochrome pathway. , 2012, Physiologia plantarum.

[36]  Ulrich Kutschera,et al.  Phototropic solar tracking in sunflower plants: an integrative perspective. , 2016, Annals of botany.

[37]  J. Loon,et al.  Simulated microgravity, Mars gravity, and 2g hypergravity affect cell cycle regulation, ribosome biogenesis, and epigenetics in Arabidopsis cell cultures , 2018, Scientific Reports.

[38]  R. Herranz,et al.  Functional alterations of root meristematic cells of Arabidopsis thaliana induced by a simulated microgravity environment. , 2016, Journal of plant physiology.

[39]  Anushya Muruganujan,et al.  PANTHER version 14: more genomes, a new PANTHER GO-slim and improvements in enrichment analysis tools , 2018, Nucleic Acids Res..

[40]  Robert J Ferl,et al.  Organ-specific remodeling of the Arabidopsis transcriptome in response to spaceflight , 2013, BMC Plant Biology.

[41]  J. Loon,et al.  The Large Diameter Centrifuge, LDC, for Life and Physical Sciences and Technology , 2008 .

[42]  S. Wyatt,et al.  Transcriptome and proteome responses in RNAlater preserved tissue of Arabidopsis thaliana , 2017, PloS one.

[43]  Simon Gilroy,et al.  Variation in the transcriptome of different ecotypes of Arabidopsis thaliana reveals signatures of oxidative stress in plant responses to spaceflight. , 2019, American journal of botany.

[44]  Yuhong Tang,et al.  Transcriptional response of Arabidopsis seedlings during spaceflight reveals peroxidase and cell wall remodeling genes associated with root hair development. , 2015, American journal of botany.

[45]  Philippe Bardou,et al.  jvenn: an interactive Venn diagram viewer , 2014, BMC Bioinformatics.

[46]  Robert J Ferl,et al.  ARG1 Functions in the Physiological Adaptation of Undifferentiated Plant Cells to Spaceflight. , 2017, Astrobiology.

[47]  W. Huber,et al.  which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. MAnorm: a robust model for quantitative comparison of ChIP-Seq data sets , 2011 .

[48]  E. Brinckmann,et al.  ESA hardware for plant research on the International Space Station , 2005 .

[49]  T. Hoson,et al.  Signal perception, transduction, and response in gravity resistance. Another graviresponse in plants , 2005 .